# Find total set bits from 0 to (2^n) - 1

Let us define F(n) as

``````F(n) = total set bits in binary representation of 0 to (2^n) -1.

Eg:

F(1) = number of bits set in 0 + number of bits set in 1 = 1
F(2) = number of bits set in 0 + ...... number of bits set in 3 = 4
``````

Is there a O(log n) algorithm to calculate F(n) where n can be as large as 10^6.

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possible duplicate of Finding the total number of set-bits from 1 to n – Jayram Singh Jun 29 '13 at 4:33
sorry but how is this a duplicate – khirod Jun 29 '13 at 4:36
when n = 10^6 then 2^n is quite a large number and cannot be calculated from what you pointed out – khirod Jun 29 '13 at 4:37
What is "binary representation of 0 to 2^n -1"? That's a series of numbers, and the binary representation of a series of numbers needs to be specified. – Potatoswatter Jun 29 '13 at 4:40

If you are asking for the number of bits set in the binary representations of all the integers from 0 to 2n–1, it's simple:

1. There are n bits in such a number.
2. There are 2n such numbers.
3. Each place-value is set in exactly half the numbers of the set.
4. The number of set bits is half the number of total bits.
5. The number of set bits is n × 2n ÷ 2 = n × 2n–1.

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its not 2^(n-1). I want it for (2^n)-1. – khirod Jun 29 '13 at 4:47
@khirod Okay, fixed, although it's not rocket science to increase the argument by one. – Potatoswatter Jun 29 '13 at 4:48

I smell homework so Im leaving out code

A simple solution , using the fact that for the ith least significant bit, answer will be

``````(N/2^i)*2^(i-1)+ X
where X = N%(2^i) - (2^(i-1)-1) iff N%(2^i)>=(2^(i-1)-1)
``````

Consider the ith least significant bit(1 based indexing) for numbers from 1 to N , then they repeat with a period equal to 2^i.And in the period , first half of the values are 0 and the next half are ones.For example :- For numbers from 0 to 7,(0 will contribute nothing so no effect)

``````000
001
010
011
100
101
110
111
1st least significant bit = 01010101 Period=2
2nd least significant bit = 00110011 Period=4
3rd least significant bit = 00001111 Period=8
and so on.

So for the ith least significant bit ,answer will be (N/Period)*(Half of Period Size) + (N%(2^i - 1) - Half of Period Size + 1)
The second term will only be taken when N%Remainder is greater than or equal to Half of Period Size.
Also , N%(2^i) can be written as N&(2^i - 1)
``````

Courtesy : http://www.geeksforgeeks.org

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